Quite significantly, according to York University neuroscience researchers whose recent study shows that different regions of the brain help to visually locate objects relative to one’s own body (self-centred or egocentric) and those relative to external visual landmarks (world-centred or allocentric).
“The current study shows how the brain encodes allocentric and egocentric space in different ways during activities that involve manual aiming,” explains Distinguished Research Professor Doug Crawford, in the Department of Psychology. “Take tennis for example. Allocentric brain areas could help aim the ball toward the opponent’s weak side of play, whereas the egocentric areas would make sure your muscles return the serve in the right direction.”
The study finding will help healthcare providers to develop therapeutic treatment for patients with brain damage in these two areas, according to the neuroscientists at York Centre for Vision Research.
“As a neurologist, I am excited by the finding because it provides clues for doctors and therapists how they might design different therapeutic approaches,” says Ying Chen, lead researcher and PhD candidate in the School of Kinesiology and Health Science.
The study, Allocentric versus Egocentric Representation of Remembered Reach Targets in Human Cortex, published in the Journal of Neuroscience, was conducted using the state-of-the-art fMRI scanner at York U’s Sherman Health Science Research Centre. A dozen participants were tested using the scanner, which Chen modified to distinguish brain areas relating to these two functions.
The participants were given three different tasks to complete when viewing remembered visual targets: egocentric reach (remembering absolute target location), allocentric reach (remembering target location relative to a visual landmark) and a nonspatial control, colour report (reporting color of target).
When participants remembered egocentric targets’ locations, areas in the upper occipital lobe (at the back of the brain) encoded visual direction. In contrast, lower areas of the occipital and temporal lobes encoded object direction relative to other visual landmarks. In both cases, the parietal and frontal cortex (near the top of the brain) coded reach direction during the movement.
Note: Click here for an image of the state-of-the-art fMRI scanner at York U’s Sherman Health Science Research Centre, modified for this research.
York University is helping to shape the global thinkers and thinking that will define tomorrow. York U’s unwavering commitment to excellence reflects a rich diversity of perspectives and a strong sense of social responsibility that sets us apart. A York U degree empowers graduates to thrive in the world and achieve their life goals through a rigorous academic foundation balanced by real-world experiential education. As a globally recognized research centre, York U is fully engaged in the critical discussions that lead to innovative solutions to the most pressing local and global social challenges. York U’s 11 faculties and 27 research centres are thinking bigger, broader and more globally, partnering with 288 leading universities worldwide. York U’s community is strong − 55,000 students, 7,000 faculty and staff, and more than 250,000 alumni.
Media Contact: Gloria Suhasini, Media Relations, York University, 416 736 2100 x 22094, [email protected]